Functions of Autophagy in Pathological Cardiac Hypertrophy

Pathological cardiac hypertrophy is the response of heart to various biomechanical and physiopathological stimuli, such as aging, myocardial ischemia and hypertension. However, a long-term exposure to the stress makes heart progress to heart failure. Autophagy is a dynamic self-degradative process necessary for the maintenance of cellular homeostasis. Accumulating evidence has revealed a tight link between cardiomyocyte autophagy and cardiac hypertrophy. Sophisticatedly regulated autophagy protects heart from various physiological and pathological stimuli by degradating and recycling of protein aggregates, lipid drops, or organelles. Here we review the recent progresses concerning the functions of autophagy in cardiac hypertrophy induced by various hypertrophic stimuli. Moreover, the therapeutic strategies targeting autophagy for cardiac hypertrophy will also be discussed.     

LC3 is a novel substrate for the mammalian Hippo kinases,STK3/STK4

The Atg8 family protein LC3 is indispensible for autophagy and plays critical roles in multiple steps of the process. Despite this functional significance, the regulation of LC3 activity at the posttranslational level remains poorly understood. In a recent study, we report that the conserved Ste20 kinases STK3 and STK4, the mammalian orthologs of Hippo kinase, are essential for autophagy in diverse organisms, and both can phosphorylate LC3 on amino acid Thr50. STK3/STK4-mediated phosphorylation is critical for fusion of autophagosomes with lysosomes, as well as the ability of cells to clear intracellular bacteria, an established cargo for autophagy. Our discovery of a novel mode of autophagy regulation involving direct phosphorylation of LC3 by STK3/STK4 significantly enhances our molecular understanding of the autophagy process. Moreover, our findings raise the exciting possibility that STK3/STK4''s known roles in immunity are exerted through their ability to regulate autophagy via LC3 phosphorylation.     

Impact of high altitude on the hepatic fatty acid oxidation and synthesis in rats

High altitude (HA) affects energy metabolism. The impact of acute and chronic HA acclimatization on the major metabolic pathways is still controversial. In this study, we aimed to unveil the impact of HA on the key enzymes involved in the fatty acid (FA) metabolism in liver. Rats were exposed to an altitude of 4300 m for 30 days and the expressions of two key proteins involved in FA β-oxidation (carnitine palmitoyl transferase I, CPT-I; and peroxisome proliferator-activated receptor alpha, PPARα), two proteins involved in FA synthesis (acetyl CoA carboxylase-1, ACC-1; and AMP-activated protein kinase, AMPK), as well as the total ketone body in the liver and the plasma FFAs were examined. Rats without HA exposure were used as controls. We observed that the acute exposure of rats to HA (3 days) led to a significant increase in the expressions of CPT-I and PPARα and in the total hepatic ketone body. Longer exposure (15 days) caused a marked decrease in the expression of CPT-I and PPARα. By 30 days after HA exposure, the expression levels of CPT-I and PPARα returned to the control level. The hepatic ACC-1 level showed a significant increase in rats exposed to HA for 1 and 3 days. In contrast, the hepatic level of AMPK showed a significant reduction throughout the experimental period. Plasma FFA concentrations did not show any significant changes following HA exposure. Thus, increased hepatic FA oxidation and synthesis in the early phase of HA exposure may be among the important mechanisms for the rats to respond to the hypoxic stress in order to acclimatize themselves to the stressful environments.     

Acute kidney injury induced by protein-overload nephropathy down-regulates gene expression of hepatic cerebroside sulfotransferase in mice, resulting in reduction of liver and serum sulfatides

Sulfatides, possible antithrombotic factors belonging to sphingoglycolipids, are widely distributed in mammalian tissues and serum. We recently found that the level of serum sulfatides was significantly lower in hemodialysis patients than that in normal subjects, and that the serum level closely correlated to the incidence of cardiovascular disease. These findings suggest a relationship between the level of serum sulfatides and kidney function; however, the molecular mechanism underlying this relationship remains unclear. In the present study, the influence of kidney dysfunction on the metabolism of sulfatides was examined using an established murine model of acute kidney injury, protein-overload nephropathy in mice. Protein-overload treatment caused severe proximal tubular injuries within 4 days, and this treatment obviously decreased both serum and hepatic sulfatide levels. The sphingoid composition of serum sulfatides was very similar to that of hepatic ones at each time point, suggesting that the serum sulfatide level is dependent on the hepatic secretory ability of sulfatides. The treatment also decreased hepatic expression of cerebroside sulfotransferase (CST), a key enzyme in sulfatide metabolism, while it scarcely influenced the expression of the other sulfatide-metabolizing enzymes, including arylsulfatase A, ceramide galactosyltransferase, and galactosylceramidase. Pro-inflammatory responses were not detected in the liver of these mice; however, potential oxidative stress was increased. These results suggest that down-regulation of hepatic CST expression, probably affected by oxidative stress from kidney injury, causes reduction in liver and serum sulfatide levels. This novel mechanism, indicating the crosstalk between kidney injury and specific liver function, may prove useful for helping to understand the situation where human hemodialysis patients have low levels of serum sulfatides.     

Commentary: Autophagy promotes Braf V600E-driven lung tumorigenesis by preserving mitochondrial metabolism

The role of autophagy in cancer is complex and context-dependent. Here we describe work with genetically engineered mouse models of non-small cell lung cancer (NSCLC) in which the tumor-suppressive and tumor-promoting function of autophagy can be visualized in the same system. We discovered that early tumorigenesis in Braf^V600E-driven lung cancer is accelerated by autophagy ablation due to unmitigated oxidative stress, as observed with loss of Nfe2l2/Nrf2-mediated antioxidant defense. However, this growth advantage is eventually overshadowed by progressive mitochondrial dysfunction and metabolic insufficiency, and is associated with increased survival of mice bearing autophagy-deficient tumors. Atg7 deficiency alters progression of Braf^V600E-driven tumors from adenomas (Braf^V600E; atg7^−/−) and adenocarcinomas (trp53^−/−; Braf^V600E; atg7^−/−) to benign oncocytomas that accumulated morphologically and functionally defective mitochondria, suggesting that defects in mitochondrial metabolism may compromise continued tumor growth. Analysis of tumor-derived cell lines (TDCLs) revealed that Atg7-deficient cells are significantly more sensitive to starvation than Atg7–wild-type counterparts, and are impaired in their ability to respire, phenotypes that are rescued by the addition of exogenous glutamine. Taken together, these data suggest that Braf^V600E-driven tumors become addicted to autophagy as a means to preserve mitochondrial function and glutamine metabolism, and that inhibiting autophagy may be a powerful strategy for Braf^V600E-driven malignancies.     

Editorial: The vacuole vs. the lysosome: When size matters

The morphometric examination of autophagic bodies provides useful information about the mechanism and magnitude of macroautophagy, and yeast researchers frequently utilize various measurements of these structures as part of their quantification of the process. The utility of this approach, however, has led to the common misconception that autophagic bodies can be found in the mammalian lysosome, which is generally not correct.     

Editorial: Defining the membrane precursor supporting the nucleation of the phagophore

How does the phagophore form? Which membrane acts as a platform for its biogenesis? Over the years, extensive use of microscopy techniques have led to the controversial identification of multiple potential membranes as precursors for phagophore nucleation and/or for the supply of lipids to the expanding compartment. Nevertheless, none of these studies has established a direct functional link between membrane sources and autophagosome biogenesis. Addressing this point, in a recent study highlighted by a punctum in this issue, Ge and coworkers developed an in vitro approach to determine the identity of the membranes responsible for the lipidation of LC3, thus identifying the ER-Golgi intermediate compartment (ERGIC) as a potential key determinant of phagophore biogenesis.